ES2219627T3 - ELECTRONIC TRIGGER UNDERSTANDING A POWER CONDENSER OF A TRIGGER COIL. - Google Patents

Abstract

Electronic trigger comprising means (1, 6) for measuring current connected to an electronic treatment circuit (2), intended to perform protection functions and comparing the measured current with at least one trip threshold, and to a circuit power supply (5) comprising a power capacitor (C) and means (11) for regulating the voltage at the terminals of the capacitor as a function of a predetermined reference voltage (Vref), trigger characterized in that the electronic treatment circuit (2 ) comprises means for comparing the measured current (l) with a predetermined threshold (ls), lower than the trip threshold, and because the trigger comprises means for setting the reference voltage (Vref) of the regulating means (11) in a first predetermined value for a predetermined period (T), when the trigger is turned on or when the measured current (l) is equal to or greater than the predetermined threshold (ls), and in a second predetermined value, lower than the first, after said predetermined period.

Description

Electronic trigger comprising a power capacitor of a trip coil.

Technical scope of the invention

The invention relates to a trigger electronic comprising current measurement means connected to an electronic treatment circuit, intended for perform protective functions and compare the measured current with at least one trip threshold, and to a power circuit comprising a power capacitor and regulating means of the voltage at the terminals of the capacitor as a function of a default reference voltage.

State of the art

In known triggers, the coil of triggering is usually powered by a power capacitor A power circuit On the triggers on their own current, the power capacitor is charged by means of current sensors associated with the conductors of a network electrical to be protected. The power circuit usually be of the type of switched feeding, which allows to regulate the voltage at the terminals of the power capacitor.

The document US-A-4567540 describes a circuit of power comprising a power and media capacitor of regulation of the tension in the terminals of the condenser in function of a reference voltage, for an electronic trigger that comprises current measurement means connected to a electronic treatment circuit and which is intended to ensure protection functions

In current triggers, it is usually necessary  a first supply voltage of the order of 18V at the terminals of the power capacitor to ensure reliable tripping of the firing coil. A second lower supply voltage, of the order for example of 10V, enough to power the various electronic circuits of the trigger, is derived from the voltage in the trip capacitor terminals.

Since the duration of a capacitor is determined by the difference between the maximum acceptable voltage for the capacitor (nominal capacitor voltage) and the actual voltage of use, the reliability of the trip capacitor requires the use of capacitors of sufficient size.

Object of the invention

The invention aims to offer a trigger to maintain or increase the reliability of the tripping capacitor, while reducing the size and cost of East.

According to the invention, this objective is met because the electronic treatment circuit comprises means of comparison of the current measured at a predetermined threshold, lower than the trigger threshold, the means comprising the trigger to set the reference voltage of the regulation means on a first default value for a predetermined period, when the trigger is turned on or when the measured current is equal to or greater than the predetermined threshold, and in a second value predetermined, lower than the first, after said period predetermined.

According to a development of the invention, the second value of the reference voltage is less than the required voltage to activate a trigger trigger coil.

Brief description of the drawings

Other advantages and features will be more clearly highlighted in the description that follows in a way particular embodiment of the invention provided by way of non-limiting example, and represented in the attached drawings, in those who:

Figure 1 schematically represents a electronic trigger according to the prior art.

Figure 2 represents a circuit of feeding of a trigger according to the prior art.

Figure 3 represents an embodiment particular of a trigger according to the invention.

Figures 4a and 4b respectively illustrate the variations, as a function of time, of the voltage at the terminals of the power capacitor and a power signal from the electronic circuits of a trigger according to figure 3.

Figure 5 represents a particular way of realization of a flow chart of operation of a circuit feeding a trigger according to figure 3.

Description of a particular embodiment

An electronic trigger according to the technique above is illustrated in figure 1. They have only been represented in the figure the necessary elements for the understanding of the invention. Current sensors 1, associated with conductors of a power grid to protect, send to an electronic circuit of treatment 2 signals representative of the circulating currents In the drivers. The electronic treatment circuit 2, preferably equipped with a microprocessor and intended to perform protection functions, compare the measured currents with at least a trigger threshold and sends a trigger signal D in case of failure, for example in case of overload or short circuit. The trigger signal D is applied to a control electrode of a electronic switch 3, constituted for example by a thyristor. The closing of the electronic switch 3 by a trigger signal D causes the excitation of a trip coil 4, connected in series with the electronic switch on the terminals of a first voltage of supply V_ {1}.

The first supply voltage V_ {1} is supplied by a power circuit 5. On the triggers by its own current, the power circuit 5 is fed by means of current sensors associated with the conductors of The power grid to protect. The current sensors connected to the power circuit can be current sensors 1 or, as shown in figure 1, different current sensors 6 of the precedents. In the latter case, the current sensors 1 They are preferably air core sensors, consisting of example by Rogowski's toroidal nuclei, while the 6 current sensors are preferably core sensors iron.

Power circuit 5 supplies also a second supply voltage V2, less than the first, enough to feed the various electronic circuits of the trigger.

Typically the power circuit 5 is of type of switched supply, which allows to regulate the voltage in the terminals of the power capacitor. In the mode of particular embodiment depicted in figure 2, the sensors of current, 1 or 6, are connected to a rectification circuit 7, preferably of the type of rectifier with double alternation, which It comprises two output terminals, one of which is connected to ground and the other to a conductor 8. An electronic switch 9, which It acts as a disconnector, is connected in parallel in the output terminals of the rectification circuit. A first terminal of power circuit 5 output, which supplies the first supply voltage V_ {1}, is connected to conductor 8 by mediation of a diode 10, which is connected to conduct conduction when the voltage at the output of the rectification circuit 7 is greater than V_ {1} and that is blocked in the opposite case. A capacitor C is connected in parallel to a voltage divider, between the first output terminal of the power circuit 5 and the grounding. The voltage divider is a resistive divider constituted by first and second resistors R_ {1} and R2 connected in series. The intermediate point of the divisor resistive is connected to an input of a regulation circuit 11, which controls the electronic switch 9. A third resistor R 3 is connected in series with a Zener Zd diode, in parallel to the capacitor C, constituting the common point of the third resistor R 3 and the Zener diode Zd a second terminal of power circuit 5 output, which supplies the second supply voltage V_ {2}.

The voltage V 3 at the intermediate point of the resistive divider is representative of the voltage V_ {1} in the capacitor terminals. As long as the voltage V_ {3} is less than a predetermined reference voltage, the regulation circuit 11 keeps electronic switch 9 in the open position (blocking in the case of a transistor). The conductor C is therefore loaded, by means of rectification circuit 7 and diode 10, a from the current transformers. As for the tension V_ {3} reaches the reference voltage, the regulation circuit 11 closes the electronic switch 9 (driving in the case of a transistor), thus short-circuiting the output of the circuit rectification. Diode 10 is then blocked, preventing the Driver C continue charging. The first supply voltage V_ {1} is thus regulated to the value of the reference voltage default The second voltage of power supply V2 on the terminals of the Zener Zd diode.

In known triggers, the reference voltage so as to always ensure a trip Trigger coil safety in case of failure. By way of example, if the voltage required for reliable coil trip of trip 4 is of the order of 18V, 19V is set as the value of the reference voltage

The trigger according to the invention represented in Figure 3 is distinguished from the above described because the circuit of regulation 11 comprises a supplementary input connected to a supplementary output of the electronic treatment circuit 2 of the trigger. The electronic treatment circuit 2 causes a modification of the reference voltage of the regulation circuit 11 so that it adopts a first predetermined value during a predetermined period, when the trigger is set to the voltage or when the measured current l is equal to or greater than a threshold default ls, lower than the trigger threshold, and one second default value, lower than the first, after that period predetermined.

The operation of a trigger according to the The invention will be explained in more detail in relation to the Figures 4a, 4b and 5.

At the time of commissioning, that is, when the trigger is turned on, the voltage V_ {1} in the capacitor terminals C is null. The electronic switch being 9 open, the capacitor begins to charge. The tension V_ {1} increases There comes a time t_ {1} when it reaches a value enough, for example 8V in figure 4a, to power the trigger electronic circuits and especially the circuit treatment electronic 2. A power signal A (figure 4b), so far at 0, then takes the value 1, starting a phase F1 start-up (figure 5) of the circuit microprocessor electronic treatment. This one then zeroes, in one phase F2, a magnitude \ Deltat, after which it sets, in a phase F3, the value of the reference voltage Vref at a first value. In the particular embodiment represented, this first value of the reference voltage is 19V. Under the control of the circuit treatment electronic 2, the regulation circuit 11 uses this first value of the reference voltage for a period default T, for example between 10 milliseconds and 100 milliseconds

Then the microprocessor verifies, in one stage F4, if the period T has ended (\ Deltat = 1 s?). If that's the case (Yes output of F4), then modify, in a step F5, the value of the reference voltage Vref, which takes a second, lower value to the first. In the particular embodiment represented, this Second value of the reference voltage is 10V. Under control of the electronic treatment circuit 2, the regulation circuit 11 uses this second value of the reference voltage from a moment t_ {2} (t_ {2} = t_ {1} + T). The capacitor C is discharge then until the voltage at its terminals reaches the Second reference value. This value is chosen so that is sufficient to ensure reliable feeding of the electronic circuits of the trigger, that is, in the mode of particular embodiment represented must be greater than 8V, and to the lower than the voltage required to ensure activation Reliable trigger coil. If period T has not ended (output No of F4), the microprocessor passes to a stage F6, in which increase the magnitude \ Deltat (\ Deltat = \ Deltat + 1), before of making a loop in step F4.

After step F5, in which the voltage of reference has passed to the second value, the lowest, the microprocessor monitors (step F7) the eventual overcoming of a default ls threshold, lower than trigger threshold, per part of the measured current l (l? ls?). While the current measure remains below this threshold (output No of F7), the reference voltage does not change and the microprocessor continues its monitoring the evolution of the current by looping in the stage F7.

If, at a time t_ {3}, the measured current reaches or exceeds the threshold ls (Yes output of F7), the microprocessor Loops in stage F2. The reference voltage Vref picks up then the first value, the highest, and the capacitor C is recharge until this value is reached. Exceeding the threshold ls by part of the current indicates that it has exceeded its normal value and It is an indication of the possibility of the impending detection of a fault that should lead to a shot. By way of example, being ln the rated current of the trigger, the threshold ls can be the same to 2 ln. If during period T, which follows the time t_ {3}, the electronic treatment circuit 2 does not detect any failure, the reference voltage returns to its second value after this period. But if, on the contrary, in fact a fault is detected during this period, a trigger signal D is then sent, in the moment t_ {4} in Figure 4b. The firing coil 4, properly fed by capacitor C, which just recharging, then causes the interruption of the current in the network to protect. Then the power circuit 5 is no longer powered by current sensors and capacitor C will download. At a time t_ {5} the voltage at the terminals of the capacitor is insufficient to properly feed the electronic circuits of the trigger (A = 0). Typically, the microprocessor takes measures to safeguard certain data during the period t_ {4} -t_ {5} that follows the shot.

In the embodiment of Figure 5, the Specific values (19V and 10V) of the reference voltage are set during stages F3 and F5, these values being then transmitted to the regulation circuit 11. In a variant of realization, the two values that the tension of Vref reference are predetermined inside the circuit regulation and the microprocessor only transmits to the circuit regulation a binary signal representative of the value to be be used

The invention thus reduces the size, and by therefore the cost, of the coil capacitor C of the coil shot 4, while ensuring reliable operation of the latter in failure case. Since a shot is a relatively phenomenon rare, the capacitor is only fully charged for short periods, of 1s for example, during which it is susceptible to fail, in this case, when the trigger is set to the voltage and when the measured current reaches a threshold ls predetermined. As an example, a 22 µF capacitor with a maximum voltage of 35V, can be replaced by a capacitor of 22 µF with a maximum voltage of 25V. Since the distance between the maximum capacitor voltage and the operating voltage goes from 35V-19V, that is 16V, at 25V-10V, is say 15V, the duration and reliability of the capacitor are maintained practically, despite the appreciable reduction in its size and cost. And conversely, keeping the size of the capacitor is can achieve a large increase in duration and therefore of the condenser reliability.

The invention is not limited to the modes. particular embodiments described above. I especially don't know limits to a switched supply of the type that lowers the voltage, but also applies analogously to the case of a Switching power of the type that raises the voltage.

Claims (5)

1. Electronic trigger comprising means (1, 6) for measuring the current connected to an electronic treatment circuit (2), designed to perform protection functions and comparing the measured current with at least one trip threshold, and at a power circuit (5) comprising a power capacitor (C) and means (11) for regulating the voltage at the terminals of the capacitor as a function of a predetermined reference voltage (Vref), trigger characterized in that the electronic treatment circuit (2) comprises means for comparing the measured current (l) with a predetermined threshold (ls), lower than the trip threshold, and because the trigger comprises means for setting the reference voltage (Vref) of the means (11) of regulation at a first predetermined value for a predetermined period (T), when the trigger is turned on or when the measured current (l) is equal to or greater than the predetermined threshold (ls), and in a second predetermined value, lower than the first, after said predetermined period. 2. Trigger according to claim 1, characterized in that the second value of the reference voltage (Vref) is lower than the voltage required to activate a trigger coil (4) of the trigger. 3. Trigger according to one of claims 1 and 2, characterized in that the regulation circuit (11) comprises an input connected to an output of the electronic treatment circuit (2). 4. Trigger according to any one of claims 1 to 3, characterized in that the predetermined period is between 10 milliseconds and 100 milliseconds. 5. Trigger according to any one of claims 1 to 4, characterized in that the supply circuit (5) is a switched supply.